Systemic Innovation: Triple Helix, Scalar Envelopes, or Regional … · 2020-05-13 · Systemic...
Transcript of Systemic Innovation: Triple Helix, Scalar Envelopes, or Regional … · 2020-05-13 · Systemic...
Systemic Innovation: Triple Helix, Scalar Envelopes, or Regional Knowledge Capabilities, an Overview. Phil Cooke, Centre for Advanced Studies & Centre for Social & Economic Analysis of Genomics, (CESAGen), Cardiff University, 44-45 Park Place, Cardiff, CF10 3BB, Wales (UK) April 2004 Prepared for International Conference on Regionalisation of Innovation Policy – Options & Experiences, Berlin, June 4-5, 2004 Abstract This paper proposes to review and assess social scientific debate about the origins and nature of innovation in modern society. The paper focuses on three sub-sets of conceptualisation, critique and commentary that refer specifically to sub-national or regional innovation systems. Research in the latter field has grown enormously in recent years. Moreover, new perspectives from other disciplines than regional science have been promoted. One distinctive view of relevance in that it is focused on the role in innovation of specific ‘entrepreneurial universities’ in relation to industry and government is, of course, the ‘Triple Helix’ approach. This is reviewed and sympathetically critiqued. A second view, less sympathetically critiqued here, is one that itself attacks all so-called ‘new regionalism’ for stressing the importance of institutions, industry embeddedness and the micro-science of regional economic development. Dazzled by globalisation and the totalising power of ‘scale’ geographies, this rejection of the worth of spatial analysis at less than the global or national ‘scalar envelope’ is assessed for its potential insights into weaknesses of the regional innovation systems approach but found wanting in both technical accuracy and scholarly competence. Finally, the state of the art in regional innovation systems research is sketched by reference both to recent longitudinal findings and elaborations into specific technological fields, particularly Bioregional Innovation Systems that help move us towards a newer theory of economic geography in the knowledge economy, based on ‘regional knowledge capabilities’.
1. Introduction As new fields settle and evolve, they diversify. Such has been the profile of innovation systems
research since it’s first elaboration in 1987.1 To manage what is becoming a substantial field of
research while focusing on elements arising from debate that may not have received sufficient
attention this paper takes stock, reviewing progress and responding to critique. The regional field of
innovation systems analysis has grown exponentially since 1992 such that recent research shows
how by 2000, refereed articles on regional innovation were equivalent to those on national systems,
and way ahead of those on technological or sectoral systems. Over 200 regional innovation systems
studies were published from 1987-2002, with more than one hundred of these empirically based.
New papers are published monthly and MIT, for example, now has an international comparative
programme managed by its Industrial Performance Centre.2
One distinctive view of relevance in that it is focused on the role of specific ‘entrepreneurial
universities’ in relation to industry and government is, of course, the ‘Triple Helix’ approach.
It can be said to operate intellectually at two ‘levels’, one a high level of abstraction in which
macro-institutions like ‘industry’, ‘universities’ and ‘government’ are held to engage in more
systemic interaction nowadays as the exigencies of the knowledge economy and competitiveness
through innovation demand greater scientific involvement in production. The second is quite ‘local’,
in that the exemplar ‘Triple Helix’ university is MIT and much of its impact through academic
entrepreneurship concerns Massachusetts, particularly Greater Boston, as well as at the scale of
North America and to a lesser extent, the rest of the world (e.g. the Cambridge-MIT partnership
funded at $100 million by the UK Treasury to raise academic entrepreneurship by knowledge
transfer). Particular studies of Triple Helix cases thus frequently focus on the impact on local-
regional economies of universities like Stanford, Cambridge, Grenoble, Washington, Linköping and
Oulu. However the approach can be criticised for emphasising the consensus aspects of relations
among such distinctive ‘epistemic communities’ and a somewhat ‘cybernetic’ view of innovation
accordingly.
A second category of what can best, at present, be considered a critique of the idea of systemic
innovation, on the one hand, and regional-local analysis on the other, is that which seeks to re-assert
the hierarchical power of geographical scale in understanding innovation processes. Thus far, this
approach enjoys the luxury of having advanced no empirical evidence for its assertions. However its
critique, and advocacy of a conception of space as a hierarchical nesting within a ‘scalar envelope’
warrants at least a response, but more importantly it may serve some purpose in reminding regional
1 This was C. Freeman’s (1987) Technology Policy & Economic Performance: Lessons From Japan, London, Pinter 2 MIT Industrial Performance Centre – Local Innovation Systems Project. http://ipc-lis.mit.edu/intellectual.html
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scientists to make doubly clear their use of the term ‘regional’ is relational not containerised, while
stimulating us to think of clearer ways of capturing theoretically the multi-level nature of innovation
inputs and outputs. At present the view of innovation in this approach is strictly linear, whereby
power to effect action resides most at the highest ‘global’, sometimes ‘glocal’ and/or national levels
and local-regions merely have these effects inscribed upon their undefined ‘scale’. Critique of this
approach is of its determinism and reification of the abstraction ‘scale’. However critique from
within geographical sciences that inverts directionality, arguing for ground-up causality, betrays an
equivalent inability to escape the confines of linear thinking, something of which the final approach
can hardly be accused.
What is here termed the ‘regional knowledge capabilities’ approach is the result of much recent
thinking from within the regional innovation systems model about the real nature of innovation on
the ground. This also partly connects to important interventions on the nature and location of
‘localised knowledge spillovers’ (LKS). Taking the latter first, there is also a ‘debate’ between those
for whom the geographical setting of, for example, a cluster stimulates accomplished absorption of
knowledge spillovers, while for critics of this view the argument is that these are not demonstrated
to be capabilities beyond those of firms residing in a given cluster. A resolution recently proposed is
to seek to understand knowledge spillover exploitation as a facet of firm resources or ‘dynamic
capabilities’ rather as Penrose argued in 1995 she would have called ‘knowledge networking’ had
that language been available in 1959 instead of the general term ‘resources’.3 Such dynamic
capabilities, where present, stimulate knowledge transfer spiralling, that is complementary
upgrading, and where it engages also innovation institutions, pulls them up the knowledge spiral.
This helps understanding of spatial variation in the geography of innovation, since some LKS
locations are more accomplished than others, which also tends to undermine the critique of the
‘scalar envelope’ approach, as this is obviously not a linear process. Crucially, research (rather than
big institutions) becomes a key asset in knowledge spiralling as is recognised in some actual
practices.
2. The Triple Helix Approach
One of the earlier forms of advocacy for a view that is consistent with local-regional innovation
networking was Etkowitz & Leydesdorff’s (1997) model of the ‘Triple Helix’ whereby in a swiftly
emerging knowledge economy as they saw it, those places with research universities would
increasingly see growing demand for knowledge transfer to industry and, through government, to
society. Moreover, the spread of universities is reasonably uniform over space. For research
3 Penrose, E. (1959/1995) The Theory of the Growth of the Firm, Oxford, Oxford University Press
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knowledge, industry and government would be willing to pay more for privileged access to
knowledge-based growth opportunities by funding more research, stimulating closer interactions
among the three institutional partners, subsidising infrastructure (e.g. incubators and science parks)
and stimulating academic entrepreneurship skills and funding. The exemplar par excellence of this
phenomenon is Massachusetts Institute of Technology. In reference to this, Gunasekara (2004)
examines in detail the validity of the Triple Helix model in wholly different contexts in Australia.
Not surprisingly he finds a model design based on MIT works poorly for the more average
universities and regions that act as his laboratory. Nevertheless, the principles hold of Triple Helix
rapprochement among such distinct ‘epistemic communities’ (Haas, 1992) as the three implied, but
the boundary-crossing effort required can defeat the unwary.
A further problem is that the Triple Helix model is inadequately ‘contextuated’, a criticism made of
Gibbons et al. (1994) for a failure to recognise the role of social movements in shifting innovation
targets, as with the impact of various ecological movements on mammalian testing, nuclear and
genetically modified food science. Nowotny et al., (2001) have auto-critiqued their earlier work
with Gibbons et al. (1994) because it remained rather lofty and science-centric whereas socio-
economic context is rather seen to be causing science and society to ‘co-evolve’ in their
development. Thus, for example, as society turned against nuclear physics because of its unsolved
pollution problems, and sought greater resource attention for healthcare, so science policy shifted
from physics and chemistry to biosciences. Thus in this context knowledge capabilities include
receptivity to social concerns in institutional and organisational processes that integrates
transdisciplinary communities of practice to form knowledge for policy learning and innovation.
Examples of this way of thinking and operating are analysed in Sotarauta’s (2004) study of research
rather than university-led regional development in rural Finland. Thus Epanet in Finland’s Vaasa-
Suomi region connects 20 new Chairs and Research Centres in collaborating counties, none of
which has a university. This Filial model affiliates professors and centres to at least 6 universities
elsewhere, thus negating the sunk costs, inertia, and vested interests of traditional ‘bricks and
mortar’ academe. In Italy, disappointment with traditional universities as regional development
engines has led to diffusion of the Pisa model of Scuoli Superiore or Advanced Study Institutes to
five ‘laboratory’ regions (Puglia, Umbria, Marche, Lombardia, and Campania) to emulate Pisa’s
Institute-Corporate-Spinout system that has been judged a success (OECD, 2001). These new
approaches recognise the weakness of universities per se as knowledge transceivers, but the
centrality of research knowledge to future regional development potential. Nevertheless Triple Helix
thinking draws attention to the broad outlines of important contemporary innovation interactions.
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3. Scalar Envelopes
A broader attempt to capture the integrative and interactive nature of the knowledge economy
examined from the regional perspective is contained in early work on regional innovation systems
(Cooke, 1992; Cooke & Morgan, 1994). In the first of these, the systemic innovation dimension of
the analysis evolved from a primary interest at that time in innovation arising from knowledge
networks and processes of networking. It is noteworthy that neither article cross references any
work on national innovation systems, suggesting the regional variant was sui generis. However,
formally the ‘innovation systems’ discourse was, in Marshallian terms, ‘in the air’. The list of
networking partners included the base institutions like universities, research laboratories, research
associations, industry associations, training agencies, technology transfer organisations, specialist
consultancies, government development, technology and innovation advisory agency programme-
funding, and private investors. This knowledge exploration, examination and exploitation base
supported the innovation efforts of large and small firms in many industries. A regional innovation
system was not a cluster, but capable of supporting numerous clustered and non-clustered industries.
Not all interactions were perceived as only intra-regional, many were national and global, but in the
most accomplished regional economies a majority of such institutional networking interactions
were, and on such regular terms that the networking had become systemic (for case material, see
Cooke, 2001).
To return to the sceptics from economic geography, it is necessary to say a little about the
historical context of the discipline. As with many things, such as a historic failure to provide a
convincing theory of location and city formation (on this, and a solution, see Krugman, 1995)
there has been since the dawning of modern geography an inability by its practitioners to carve
out a core area of theoretical competence of the status of, say ‘class’ or ‘structuration’ in
sociology, the ‘Phillips curve’ explanation of the relation between unemployment and inflation in
economics, or ‘multi-level governance’ in political science.
The last-named is of direct relevance to issues tackled in this paper, so what do it’s leading
propositions say? First that different levels of governance relate not in a linear, power-imposing
manner, but by evolving spheres of capability among which interactions occur by negotiation
between parties of consequence to specific competence areas. Study then focuses on change or
evolution, including devolution, of such competences and capabilities as political systems
mature. As the book reporting first findings from eleven systematically selected and hypothetic-
deductively analysed European regions (Cooke, Boekholt & Tödtling, 2000) showed, it is
impossible to discuss innovation processes and policies without reference to the interactions of
local-regional, national and global actors and institutions. This will be especially vividly revealed
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in the brief exemplar account in Section 5 of fascinating global-regional bioscientific innovation
systems involving the small nation-big pharma practices of the Swiss corporate pharmaceuticals
sector.
This allows contrasts of the following kind to be drawn with confidence by exponents of multi-
level governance, in this case referring to the relations between national and regional electoral
outcomes. Germany demonstrates a predictable relationship between regional and national
outcomes since strong regional differentiation in voting is exceptional. Spain’s relationship of
regional to national elections is complex due to distinctive regional electoral dynamics arising
from historical, cultural and linguistic expressions of difference in specific regions. Canada’s
regional and national electoral dynamics are mostly decoupled because of historical, cultural
linguistic expressions of difference (Hough & Jeffery, 2003). The explanation is that there is
geographical variation in what counts as first and second order political issues for the electorate.
In other words, the larger ‘scale’ does not always, or indeed ever, impose its will on the lesser.
For how, as an abstraction, could it?
Contrast this with an eclectic mixture of critique, comment and conceptualisation on the issue of
‘scale’ emanating from contemporary economic geography. Already early in being attacked by
Dicken et al. (1997) for a conservative, linear determinism that sees ‘globalisation’ as a
totalising, relentless and inevitable power, it proceeds in an all-encompassing way to deny
capability to other ‘scales’. Trying to escape this we see, for example, Bunnell & Coe (2001) and
Mackinnon et al. (2002) saying it is both wrong to emphasise the regional level and wrong to
overlook regional specificity. Scale clearly does not exclude presence of fences for sitting upon.
This is an improvement upon Listian positions such as that of Bathelt (2003) writing that only
nations have specificity and that they may also be closed systems, which in a world of liberal
free trade and widespread immigration may serve only to unite in scepticism the ‘glocalists’ (e.g.
Swyngedouw, 1997), with those whose interests are also in the sub-national domain. This latter
commentary on closure, albeit moderated in ways that still privilege the national over any other
scale, is especially curious, for it essays two impossible feats. The first is to advocate a
nineteenth century unitary view of the contemporary relation of the nation (state) to its regions,
namely their annihilation that is simply factually wrong4. This is particularly evident in the
contemporary EU, in which ‘region formation’ has and continues to be evolved apace. Second,
the sceptics attack for inattention to scale issues, authors who have empirically demonstrated
precisely the presence of regional governance capabilities. These exist even where regional
4 We discuss this further below in terms of the etymological meaning of ‘region’, which turns out to be perfectly compatible with its meaning in connection with ‘regional innovation systems’.
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‘government’ is absent, and display accomplishment at managing economic development and
innovation support actions where national governments may have been inactive in such spheres
(e.g. Asheim & Isaksen, 2002).
This resonates with a recent critique of the ‘scalar envelope’ scepticism of regional innovation
systems thinking from Morgan (2004). In a cogently argued response he defends in the following
manner. First, regional innovation systems analysts are said to ‘take regions for granted as objects of
analysis by failing to consider how they have been historically institutionalised as spaces of
political-economic intervention and action’ (MacKinnon et al, 2002; MacLeod, 2001). This is
clearly mistaken since this approach treats the region as ‘a nexus of processes’ precisely in an effort
to highlight the dynamic tensions inherent in the evolutionary process of socio-spatial change at the
sub-national level (Cooke and Morgan, 1998) Moreover in each empirical case the evolution of the
regions in question is profiled to show how they had been historically constituted.
The second criticism concerns ‘a neglect of external networks and institutions, such as those
associated with transnational corporations and nation states’ (MacKinnon et al, 2002).
But in this approach to the governance dimension it is consciously shown how to circumvent these
theoretical problems by locating each regional case study firmly within its national system of
innovation. Regarding transnational corporations, while the approach is mainly concerned to
explore the endogenous capacity for regional development in regional cases, this does not confuse
endogenous capacity with indigenous capacity. In any case in such studies, the role of Foreign
Direct Investment (FDI) and knowledge collaborations and codified knowledge uptake from global
sources is normally part of the analysis. And, where systems host indigenous transnationals, the
other end of the spectrum is examined, notably how large firms, possibly hitherto part of a
regionally embedded system of production, engage in belated globalisation. Finally, critics of
regional innovation systems analysis attack ‘the tendency to provide snapshots of successful
regions’, so that research ‘fails to address questions of adaptation and renewal in terms of how
regions can sustain growth in the face of rapid changes in technologies and markets which may
threaten the basis of such growth’ (MacKinnon, 2002). This too misses the mark since adaptation
and renewal are the most prominent themes of the evolutionary analyses that commonly denote
regional innovation systems research. Moreover, such work shows how even ‘successful regions’
also have to negotiate the problems of adaptation and renewal, an important difference being that
the former have more capacity to re-invent themselves.
Thus, outside the rigours of theoretically and empirically informed regional innovation systems
analysis the field of economic geography (here defined as the preoccupation with regional economic
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development) remains ridden with conceptual fuzziness. As a consequence, rather than producing
well-defined empirical categories; a series of testable propositions; and clear policy advice,
economic geography tends to be dominated by (ideographic) case studies, broad (and untestable)
stylised statements on what propels regional economic development, or, even less productive, high-
level theory discussions that remain uncoupled to real-world experience.
Hence we cannot support the linear, hierarchical determinism of the ‘scalar envelope’ approach
with its weak grasp upon ‘agency’. For this flies in the face of research that shows sub-national
policy mobilisation regarding shaping of innovation capabilities to be common, if not yet
ubiquitous (for a progenitor of spatial ‘enveloping’, see Brenner, 2001). But we go further in re-
asserting the relevance of the ‘regional’ as denoted above to the study of innovation, and recent
extensions of analysis of the processes involved backwards along the knowledge value change
into knowledge exploration and production itself, by speaking of ‘regional innovation’. This
contested term is considered an artifice principally by those wedded to an increasingly
questionable notion that economies are only characteristic of a national scalar envelope (e.g.
Brenner, 2001; Bathelt, 2003; for a penetrative critique, see Nielsen & Simonsen, 2003).
However, we have seen how the now settled ‘globalisation’ debate undermined that comforting
presumption by demonstrating the significance of the greater extensive and intensive integration
of global value chains and industry organisation occasioned by the intersection of multinational
firms and local-regional clusters on a worldwide basis (see, for example, Gereffi, 1999;
Henderson et al., 2002; UNIDO, 2002). This means rejection of any ‘containerised’ notion of
economic flows. For example, we disagree with Bathelt (2003) that:
‘...only a few regions can be characterised as being economically self-sufficient hosting a
full ensemble of related industries and services which could serve as a basis for the
establishment of an innovation system.’(Bathelt, 2003, 796)
because it is impossible, in a globalised world economy, to envisage a country including, for
example, the USA in that happy position, let alone a region as defined here as a subnational
governance entity. In January 2002, the US began running, for the first time, a monthly trade deficit
in advanced technology products like biotechnology and other leading edge technologies (Library of
Congress, 2003). It has, of course imported a massive amount of intellectual capital since time
immemorial (Saxenian, 2000).
There is a clear connection here to literature recognising interdisciplinary interaction as a key
feature perceived to characterise emergent ‘Mode 2’ knowledge production (Gibbons et al., 1994).
Traditional scholastic disciplines rooted in large-scale teaching departments of universities (Mode
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1) were observed to be breaking down with the growth of funded academic research. Diversification
of knowledge production in specialist Research Centres that were at arm’s length from normal
pedagogic activity, capable of bridging industry-academe boundaries, as occurred most fully in the
Stanford University model described by Gibbons (2000), but also closely in touch with problem-
focused researchers from other disciplines characterised Mode 2 ‘transdisciplinarity’. Further
ingredients included also reflexivity, and networking to tackle knowledge ‘heterogeneity’. This
influential and somewhat prescient perspective was criticised later, not least by some of its authors
(in Nowotny et al., 2001) because it remained rather lofty and science-centric whereas socio-
economic context is rather seen to be causing science and society to ‘co-evolve’ in their
development. Thus, for example, as society turned against nuclear physics because of its unsolved
pollution problems, and sought greater resource attention for healthcare, so science policy shifted
from physics and chemistry to biosciences.
So we may think of the regional innovation systems capability as one that is more highly evolved
than, for example a ‘learning region’ the key functionaries in which seek to capture knowledge and
information from more accomplished institutional settings and try to apply it, not always
appropriately and probably not swiftly, to problems of development, ‘lock-in’ and path dependence
currently confronting them. The regional innovation systems appellation denotes exploration, the
quest for new knowledge, the testing of that knowledge, reflection upon it and practical application
suitably shaped to enhance the capabilities of institutions and organisations, especially firms in that
region. This implies making optimal use of ‘Constructed Advantage’ (Foray & Freeman, 1993; de
la Mothe & Mallory, 2003) from collaboration and networking across institutional boundaries that
exist in the transdisciplinary mix of communities of practice. This implies the presence of
institutional innovation networks integrating regional institutions to each other and beyond to other
regions, national systems and globally located knowledge network nodes:
“Knowledge” refers not only to research and development in the natural sciences and
engineering, but also to related scientific activities (surveys, statistics, mapping, etc.) as well
as a full range of technical, managerial, and social skills and cultural contexts.......... The way
in which institutions can identify, appropriate, apply and disseminate knowledge is by acting
as part of an innovation system. These systems include knowledge producers (such as
laboratories), knowledge users and appliers (such as firms), knowledge regulators (such as
food and drug inspection agencies, intellectual property agencies), knowledge diffusers
(including such smart infrastructure as information highways), knowledge funders (such as
granting agencies), and so on.’ (de la Mothe, 2003)
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Knowledge processing functions become the key elements of regional innovation systems in
formation or already formed.
4. Regional Knowledge Capabilities
What is a region? The concept has its origin in the Latin regio from regere meaning ‘to govern’. In
the field of regional development, this is precisely the sense of ‘region’ intended, namely
governance of policies to assist processes of economic development. So, here, the concept of
‘region’ as administratively defined is of primary importance. Moreover, taking the administrative
dimension as prior means in definitional terms the following: region is an administrative division of
a country, thus for example ‘Tuscany is a region of Italy’. Of course, there are other definitions that
explain the confusion. An abstract definition is ‘any large, indefinite and continuous part of a
surface or space’, a slightly less abstract but still vague one is ‘a unit for geographical, functional,
social or cultural reasons’, and intriguingly a military one is ‘the part of the theatre of war not
included in the theatre of operations’. Thus ‘region’ presented as abstract space, culture area, or
military backcloth. None of these captures the precision required and supplied by our preferred
definition. The final remaining qualifier is to specify ‘regional’ as nested territorially beneath the
level of the country, but above the local or municipal level. In objective terms, this is generally how
the conceptual level will align with the real. However, some countries only have national states and
local administrations, no regions. Some of these, like Finland and Sweden are evolving regional
administrations. But can those that are not be said to experience ‘regional development’? We say
unambiguously that they can, and by dint of national or even supranational policy for regional
development, or local proactivity, possibly including local collaborative partnerships of
municipalities pursuing aims of constructed advantage, they do.
Is the knowledge economy a mere artifice, a figment of the need for academics to make careers by
inventing a new buzz phrase? Why do we care about the knowledge economy? What special
implications does it have for regional economic development? We intend to give convincing
answers to each of these questions in this section, pointing briefly to ways they contribute to and
improve the current debate. In doing this we tackle the questions in the order we raised them. The
first point, perhaps surprising to some readers, we make to challenge the possible argument about
the ‘faddishness’ of the knowledge economy perspective is that it is not a new idea. Apart from
Marx, who indicated that, for example, mathematics and the natural sciences were exempt from the
direct influence of the social and economic infrastructure, and that superstructures were not only
mere reflections of infrastructures, but could in turn react upon them (see Coser, 1977), it was
Schumpeter who recognised first the importance of knowledge in the economy by his reference to
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‘new combinations of knowledge’ at the heart of innovation and entrepreneurship (Schumpeter,
1912, p. 57). Nonaka & Takeuchi (1995) also show that Marshall (1916) recognised that:
‘Capital consists in a great part of knowledge and organisation...... knowledge is our most powerful engine of production.......organisation aids knowledge’ (p. 115)
But, typically neoclassical economics neglected what was not contained in price information and
made no effort to add to economic knowledge by trying to measure its economic contribution.
Thereafter, Hayek (1945; 1948) identified ‘the division of knowledge as the really central problem
of economics as a social science’ (1948, p. 51) and its key question as addressing the puzzle of
localised knowledge held by fragmentary firms and individuals nevertheless producing ordered
market demand and supply:
‘The most significant fact about this system is the economy of knowledge with which it operates, or how little the individual participants need to know in order to be able to take the right action. In abbreviated form, by a kind of symbol, only the most essential information is passed on, and passed on only to those concerned (Hayek, 1948, p. 86)
Clearly none of these writers was writing about the knowledge economy per se but rather its
fundamental importance to the functioning of all aspects of the economy from innovation to
production, organisation and markets.
Finally, a further progenitor of the view that knowledge is the most important economic resource
was Penrose (1959). She founded what has now evolved into the ‘dynamic capabilities of firms’
approach to microeconomics (Teece & Pisano, 1996). She referenced the firm’s characteristics as an
administrative organisation (after Marshall, 1916 and Coase, 1937) and home to accumulated
human and material resources. The latter are inputs to services rendered, and these are the product
of the firm’s accumulated knowledge:
‘...a firm’s rate of growth is limited by the growth of knowledge within it, but a firm’s size by the extent [of] administrative efficiency (Penrose, 1995, xvi-xvii)
So, in effect, as it is put by Nonaka & Takeuchi (1995) ‘...the firm is a repository of knowledge’ (p.
34). Penrose (1995) also wrote that had the language been available at the time of the original
writing in the 1950s she would have referred to the dynamic capabilities of firms residing in
knowledge networks (for discussion, see Quéré, 2003). Thus Penrose (1995) notes the following
crucial feature of the massively increased value of transferable knowledge to the wider economy for
the firm:
‘...the rapid and intricate evolution of modern technology often makes it necessary for firms in related areas around the world to be closely in touch with developments in the research and innovation of firms in many centres (Penrose, 1995, p. xix)
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Importantly, Penrose continues, the rise of business knowledge networks represents a
metamorphosis in the contemporary economy. The key to the knowledge economy is at least partly
revealed as this metamorphosis in the nature of industry organisation to facilitate interaction with
rather than secrete valuable knowledge, as was common in the previous evolutionary phase of the
global economy.
This is of direct relevance to issues tackled in this paper, so what do their leading propositions say?
First that different levels of governance relate not in a linear, power-imposing manner, but by
evolving spheres of capability among which interactions occur by negotiation between parties of
consequence to specific competence areas. Study then focuses on change or evolution, including
devolution, of such competences and capabilities as political systems mature. As the book reporting
first findings from eleven systematically selected and hypothetic-deductively analysed European
regions (Cooke, Boekholt & Tödtling, 2000) showed, it is impossible to discuss innovation
processes and policies without reference to the interactions of local-regional, national and global
actors and institutions. This will be especially vividly revealed in the brief exemplar account in
Section 5 of global-regional bioscientific innovation systems involving the small nation-big pharma
practices of the Swiss corporate pharmaceuticals sector.
What defines successful or promising ‘knowledge economy’ regions and where are they?
For the moment we may take bioregions as our exemplar, but later we shall underpin this with
reference to other industries. The simple answers to the questions raised in the title of this sub-
section are that scale is the normal ranking device among relevant variables like numbers of
dedicated biotechnology firms (DBFs), size of research budgets, investment finance or number of
life scientists. On such counts, the answer about location is North America, primarily the USA. But
there are obvious weaknesses in taking scale at face value.
Thus qualitative considerations that go beyond mere numbers of firms into another scale question
regarding their turnover, sales or employment enters the discussion. Similarly, a DBF (or a
bioregion) with biotechnologically-derived products already on sale in healthcare markets, having
passed through the three trialling phases and won US Food & Drug Administration approval, would
presumably rank higher than a larger DBF or bioregion with mainly ‘pipeline’ products. Similarly
drugs are considered more important than diagnostic kits. So a location with a handful of peak
research institutes with SMEs producing cancer-defeating drugs creates more value per worker, or
more value per unit of input, and value per product sold, even though its collective return is less
than a multinational pharmaceuticals firm or firms that market and distribute some new therapeutic
treatments, traditional (fine chemistry) drugs and a range of other products, and whose market
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capitalisation is accordingly far greater. Value lies increasingly in the knowledge and organisational
resources of such non-corporate actors in this field. Creativity and content are more valuable than
the media, through which they flow, in this not especially controversial argument.
What may be controversial, however, is the argument that in knowledge-based industry, generating
and commercialising abstract, synthetic and symbolic knowledge derived from research is
increasingly to be found outside the corporate sector and inside knowledge-intensive research
institutes, consultancies and modestly-sized but regionally agglomerated firms. There are
exceptions, as always, to an emergent trend as Valentin & Lund-Jensen (2003) showed for the food
industry, something also argued from a different perspective by Smith (2001). This in turn,
however, is a product of the knowledge capabilities of the agro-food sector, in which biology is a
core research competence. But even here, it can be shown, large corporates like Monsanto and
Bayer show certain incapabilities, shared in research and, nowadays even development by large
pharmaceuticals firms. Accordingly, the agro-food bioscience industry shows signs of spawning
more specialist DBFs than hitherto5
It can be shown theoretically that the definition of a successful economic region is that it possesses
all or most of the key value-adding functions of a specific sector as well as reasonable
diversification of the economic base into other separate or connected sectors. It thus combines depth
and breadth in its industrial capabilities6. The role of spillovers or what are more traditionally
known as external economies is important here. Why would firms cluster geographically in
bioregions if there were little or no functional advantage when, according to normal supply and
demand rules, overhead costs would be higher than if clustering had not taken place. The obvious
answer is that they gain advantage from the knowledge network capabilities that bioregions contain.
These exist in the human capital ‘talent’ trained in local research institutes and university
laboratories; the presence of ‘star’ scientists and their research teams; the possibilities for
5 This is discussed in Section 5, which contains profiles of specific agro-food knowledge R&D 6 There is a stimulating debate between two schools of innovation thought on this. One says sectoral specialisation produces the best results, the other says diversification. The former position is associated with Glaeser et al. (1992) and Griliches (1992) who see specialised knowledge ‘spillovers’ as key growth propellants. The latter view begins with Jane Jacobs (1969) and is supported by, for example Feldman & Audretsch (1999) who show sectoral diversity is most strongly associated with regional innovativeness. The specialisationists emphasise markets while the diversificationists give greater weight to institutional infrastructure (innovation support system) and microeconomic linkages across agents and firms (networks) thus supporting a regional innovation systems perspective. Most recently Henderson (2003) shows specialisation effects on knowledge spillovers to have strong but short-lived impact in high technology industry while diversification effects persist far longer. This suggests that as they evolve biotechnology clusters first specialise then later diversify, firms taking distinctive advantage of external economies in the process, e.g. at first, research spillovers, later investment or ICT knowledge spillovers.
13
collaboration with like-minded research teams or other DBFs; and the presence of understanding
financial investors also attracted to the ‘ideas market’ that a biotechnology cluster represents7.
Just as there is debate, that may be approaching resolution, regarding the primacy of regional
specialisation or diversification for innovation (see fn. 6) favouring the former in the early phases of
an industry’s development, and the latter in the later phases, so there is an emerging debate about
market versus social characteristics of successful or potentially successful biotechnology clusters.
The ‘market’ perspective is propounded by Zucker et al. (1999) while a good example of the
‘social’ perspective is provided by Owen-Smith & Powell (2004). The former generate data to show
the following. They found the following regarding the propensity to cluster by DBFs and research
scientists, notably those of ‘star’ status:
• Especially in the early years, commercialisation of biotechnology required the mastery of a
very large amount of basic scientific knowledge that was largely non-codified. Thus DBFs
became inordinately dependent on research scientists to ‘translate’ for them. The latter were
well attuned to working with industry, hence receptive to such interaction. Locations with
concentrations of such knowledge to transfer thus became magnets for DBFs as ‘big
pharma’, early users and facilitators of research discovered their own absorptive capacity
problems deriving from their origins in fine chemistry not biology
• ‘Untraded interdependencies’ or pure knowledge spillovers (non-pecuniary) do not seem to
apply in biotechnology. Discoveries do not transfer swiftly through social ties or informal
seminars but rather display high ‘natural excludability’. This means biotechnology
techniques are not widely known, so ‘stars’ exploit this by entering contracts with DBFs to
exploit surplus profits. Localisation arises as the scientist interacts with proximate DBFs
because she usually retains affiliation to the academic home base.
• The innovative performance of DBFs is positively associated with the total number of
articles by local university biotechnology ‘stars’. However, further data disaggregation of
‘stars’ into those contractually tied and untied to local firms show the positive association
only applies to contractual collaborators, while the coefficient loses both significance and
magnitude for the others.
Finally, the commercialisation dimension is crucial, that is - the advantages of proximity to firms
that ‘make it happen’ i.e. help turn a scientific finding into a firm that commercialises a drug,
treatment or diagnostic test. These are venture capitalists, specialist lawyers and consultants, and
there is econometric and case study evidence that these knowledge demands cause them to locate 7 On knowledge network capabilities, the early work of Penrose (1959) has given rise to the economics sub-field of studying ‘dynamic capabilities’ of firms to understand regional and other growth processes (Teece & Pisano, 1996).
14
their investment a mean distance of one hour’s driving time from their office base for the most part8.
These are ‘pipeline’ type relationships, sealed from prying eyes and ears.
This ‘market’ perspective focuses specifically on those contractual relationships where exacting
transactions involve potentially large returns to partners from academe and enterprise. But the
alternative, ‘social’ position observes, albeit with social anthropological data, a different
characterisation of the successful or potentially successful bioregion. That success is based on the
practice of ‘open science’ transformed into a cluster convention of knowledge sharing rather than
secreting. These authors examined the Boston biotechnology cluster and highlighted the following
as key processes by which dynamic place-based capabilities are expressed in research, knowledge
transfer, and commercialisation of bioscience.
• The difference between ‘channels’ (open) and ‘pipelines’ (closed). The former offer more
opportunity for knowledge capability enhancement since they are more ‘leaky’ and ‘irrigate’
more, albeit proximate, incumbents. Pipelines offer more capable means of proprietary
knowledge transfer over great geographical distances based on contractual agreements,
which are less ‘leaky’ because they are closed rather than open.
• Public Research Organisations are a primary magnet for profit-seeking DBFs and large
pharmaceuticals firms because they operate an ‘open science’ policy, which in the
Knowledge Economy era promises innovation opportunities. These are widely considered to
be the source of productivity improvement, greater firm competitiveness, and accordingly
economic growth.
Over time the PRO ‘conventions’ of ‘open science’ influence DBFs in their network interactions
with other DBFs. Although PROs may not remain the main intermediaries among DBFs as the latter
grow in number and engage in commercialisation of exploration knowledge and exploitation of such
knowledge through patenting, they experience greater gains through the combination of proximity
and conventions, than through either proximity alone or conventions alone. This is dynamic
knowledge networking capability transformed into a regional capability, which in turn attracts large
pharma firms seeking membership of the ‘community’.
These propositions each receive strong support from statistical analyses of research and patenting
practices in the Boston regional biotechnology cluster. Thus:
8 This is a widely accepted norm in most locations testified to in research by Zook (2002) and Powell et al. (2002) among many others. It is because of the venture capitalist’s need for a ‘hands-on’ relationship with her investment, possibly ‘at the drop of a hat’. The greater the distance away from the investment, the greater the uncertainty about management control. As a case in point, Kleiner, Perkins Caufield, Byers, the leading US venture capitalist, has 80% of its so-called ‘keiretsu’ investments in biotechnology and ICT within an hour’s drive of its Sand Hills Road headquarters in Palo Alto (Cooke, 2001).
15
‘Transparent modes of information transfer will trump more opaque or sealed mechanisms when a significant proportion of participants exhibit limited concern with policing the accessibility of network pipelines…closed conduits offer reliable and excludable information transfer at the cost of fixity, and thus are more appropriate to a stable environment. In contrast, permeable channels rich in spillovers are responsive and may be more suitable for variable environments. In a stable world, or one where change is largely incremental, such channels represent excess capacity’ (Owen-Smith & Powell, 2004)
Finally, though, leaky channels rather than closed pipelines represent also an opportunity for
unscrupulous convention-breakers to sow misinformation among competitors. However, the
strength of the ‘open science’ convention means that so long as PROs remain a presence, as in
science-driven contexts they must, such ‘negative social capital’ practices are punishable by
exclusion from PRO interaction, reputational degrading or even, at the extreme, convention shift, in
rare occurrences, towards more confidentiality agreements and spillover-limiting ‘pipeline’ legal
contracts.
So we conclude the following from this analysis of two sets of competing explanations of successful
bioregions. First, as with the specialisation versus diversification debate on knowledge spillovers
which was concluded by observing the time difference in the prominence of one over the other in
the evolution of the cluster, so we conclude that transactions are ‘pipelines’ when legally binding,
confidential, contractual business is being transacted but is otherwise subject to ‘open science’
conventions. This is represented in Table 1 below. To explain what the table shows, it suggests the
following.
Specialisation Diversification Pipeline 1. Embryonic 4. High Success Open Science 2. Innovative 3. High Potential
Fig. 1: Characterisation of Successful and Potentially Successful Bioregions
In the early stage (1) of a technology, there will be few firms or academics with the requisite
combination of scientific and commercialisation expertise for technology exploitation. However
when the two come together and the market potential of what has been discovered is realised, there
will be a ‘pipeline’ type transaction to patent, arrange investment and create a firm. This was exactly
the history of Genentech after Recombinant DNA Nobel Laureate Herb Boyer and partner Stanley
16
Cohen met Robert Swanson venture capitalist with Kleiner, Perkins, Caufield & Byers in 1976
before any cluster existed in San Francisco. Thereafter (stage 2) more DBFs formed as scientific
research evolved and new DBFs sought to emulate Genentech’s success. These included Biogen in
Cambridge, Massachusetts and Hybritech in San Diego in the 1970s and early 1980s9. Once this
process has begun, the sector remains specialised but more DBFs and their employees who retain, as
do founders, close affiliation with their host university, open ‘channels’ and knowledge spillovers
are accessed to create a highly innovative environment around ‘open science’ conventions. The third
stage is reached when diversification begins and specialist suppliers, on the one hand, but more
importantly, new technology research lines and DBFs form – for example after a breakthrough like
decoding the Human Genome – on the other. Large research budgets are by now attracted to leading
centres and this stimulates further ‘open science’ communication, cross-fertilization through
knowledge spillovers and further DBF formation. Fourth, after this, many serious entrepreneurial
transactions occurring through ‘pipeline’ relations with big pharma take place, trialling proves
successful and licensing deals for marketing a healthcare product are regularly struck between big
pharma and DBFs. Then, regarding further R&D, big pharma with public-funded leading research
institutes is further engaged and a potentially successful bioregion can be said to have become
highly systematic.
5. Countering A Discourse of ‘Scale’: the Case of Basel and Its Bioscience
Basel is a small place in a small country but it hosts four or the largest bioscientific companies in
the world: Novartis10, Roche11, Syngenta (agro-food biotechnology), and Lonza.12 But Basel also
hosts many smaller DBFs as Actelion, Discovery Technologies and GeneData.13 Of the 200 Swiss
biotechnology companies listed in the Swiss Life Sciences Database14 in 2003 around 40 were pure
biotechnology firms (DBFs), the others being instrumentation and services firms that nevertheless
link to many of the forty. Some 22% of the 200 are located in the Geneva-Lausanne ‘BioAlps’
region, approximately 26% are in the Basel ‘BioValley’ region, and about 35% are in the Greater
Zurich region. Both Roche and Novartis, in particular, draw on the institutional strength of the Basel
bioregional innovation system, key institutions of which are shown in Table 1.
9 In those days the leading DBFs were all associated with leading scientists. Alongside UCSF’s Boyer with Genentech were Walter Gilbert of Harvard with Biogen, Ivor Royston of UCSD with Hybritech, Mark Ptashne of Harvard with Genetics Institute, and William Rutter of UCSF with Chiron. In the 1980s Nobel Laureate David Baltimore (MIT) founded SyStemix, Malcolm Gefter of MIT founded ImmuLogic, and Jonas Salk, Salk Institute San Diego founded Immune Response (see Prevezer, 1998) 10 Novartis employs 36,000 worldwide. 11 Hoffmann-La Roche employs 30,000 worldwide 12 Syngenta & Lonza employ 20,000 and 6,000 worldwide, respectively 13 Das (2000) holds that there were then 74 firms in Basel with a ‘…focus on various aspects of biotechnology.’ (p.3). These included Actelion (30 employees), GeneData (12), Myocontract (4), and Nekko, specialising in endothelium, bioinformatics, high throughput screening (HTS), oncology & cardiology, respectively. 14 www.swisslifesciences.com
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Location Institute Speciality Scientists Basic Research Basel Friedrich Miescher Institute Genomics, Neurosciences, 240 Plant Biology, Biochemistry Basel University Botanical Institute Molecular Plant Biology 40 Basel University Biocentre Genomics, Neurosciences 330 Cell Biology, Biochemistry, Structural Biology,
Microbiology Basel Genome Institute Genomics 50 Basel University Zoological Institute Neurosciences 60 Basel Canton Hospital Tissue Engineering 40
Applied Research
Basel Canton Hospital Oncology, Immunology, 395 Haematology, Pharmacology, Infectious Diseases, Neurosciences, Diagnostics, Cardiovascular,
Basel University Radiological Medicine Diagnostics 30 Basel Tropical Institute Infectious Diseases 35 Basel University Biocentre Pharmacology, Toxicology 50 Basel Pharmaceuticals Institute Pharmaceuticals 30 Total 3,000 Table 1: Bioscientific Capabilities, Public Research Organisations in Basel, Switzerland, 2001 Source: BioValley Science Guide http://www.biovalley.ch/main/downloads/BioValley%20Science%20Guide%20(c).pdf
From this base Roche and Novartis have been the world’s most active acquirers and partners of US,
especially Californian, DBFs, though they are not alone in having such links. In San Diego alone Eli
Lilly entered collaboration with the Scripps Institute, gaining rights of first refusal on discoveries in
exchange for $50 million. Then, in 1986 Lilly acquired Hybritech, one of the earliest DBFs, only to
dispose of it subsequently, thereafter investing in ownership of a leading diabetes therapeutic from
Ligand Pharma. In 1996 Lilly entered a collaboration with Neurocrine Biosciences, and in 2001 did
the same with Isis Pharma ($200 million). In 1996 Schering-Plough acquired Canji, a gene therapy
firm with late-stage clinical trials. Johnson & Johnson also, like Lilly, began interaction early,
entering a collaboration agreement with Scripps Institute, then in 1995 taking an 11% stake in
Amylin, enlarging this in later years. From 1995-9 it also had collaboration with Neurocrine
Biosciences and in 1996 Johnson & Johnson created an integrated Genomics Research Institute in
La Jolla, extending it in 2002 after signing a partnership deal with Maxia Pharma in 2001. Warner-
Lambert (now Pfizer) acquired Agouron Pharma, the most successful San Diego biotechnology
firm, employing 1,000 for $2.1 billion to access its HIV treatment. Pfizer began with a research
18
collaboration in 1991 with Ligand Pharma, integrated Agouron into its worldwide operations in
2000 with the acquisition of Warner-Lambert, and in 2002 opened the first stage of a new research
centre ($155 million) in La Jolla on the Agouron site. In 1999 Merck acquired Sibia Neurosciences,
invested in its research laboratories expanding them substantially. In 1998 Ireland’s Elan
Corporation entered partnership with Ligand Pharma and in 2000 acquired Dura Pharma for $1.5
billion, centralising its biopharmaceuticals operations in La Jolla, before entering 8 further
biotechnology collaborations. Finally, Japanese pharmas Chugai and Sankyo established research
facilities in San Diego in 1995 and 1998 respectively.
However, these activities pale into insignificance in comparison with Novartis’ systemic network
formation in both San Francisco and San Diego from 1977 in the former case and 1990 in the latter.
These are summarised for San Francisco in Table 2 below. The symbiotic
Year Partner Deal
1977-1988 ALZA Controlling stake – transdermal kits; divestment & collaboration, mktg. 1986-1995 Chiron Joint venture, vaccines; research agt.in growth factors. Acquires 48% of Chiron in1994; accesses gene sequencing. 1990 Protein Design Labs Research, anticancer antibodies 1991 Athena Neurosciences Anti-spasm drug in-licensing 1991-1997 SyStemix Collaboration immunology; 60% acquisition; stem cells & immunology collaboration; completes acquisition. 1992 Affymax Collaboration catalytic antibodies
1997-2001 Affymetrix Acquires Gene Chip technology 1997-1998 Incyte Pharma Bioinformatics software agreement
1997 Titan Pharma Iloperidone global marketing rights acq. 1998 UC Berkeley Licensing ag-bio discoveries, first refusal 1998 Stanford U. Transplantation technology collaboration 1999 Versicor Research collaboration, antibacterial NAS 1999 Rigel Five drug target collaborations 2000 Axys Pharma Combinatorial chemistry library access Table 2: Novartis Collaborations with San Francisco Biotechnology DBFs & Institutes (After Zeller, 2004)
integration of Novartis with the San Diego bioregion warrants deeper exploration to show how
small country big pharma gains advantage from embeddedness15 in the cluster. The strongest of
these collaborations, agreed by Sandoz in 1992 and effective from 1997, is the ten-year research
collaboration with The Scripps Research Institute (founded in 1955). It complemented in-house
15 This concept is central to the theory of clustering. It refers to the ties between firms that may be weak or strong, but proximity in clusters offers firms both kinds. However, Novartis is rather unusual in establishing very strong ties with San Diego institutions and firms. This is true also for San Francisco, and, as we shall see Boston.
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research by Novartis in immunology, neurological science, and cardiovascular diseases by giving
first access to Scripps research results in these fields, and the right to commercialise 47% of Scripps
discoveries. Controversial because of infringing ‘open science’ conventions the initially agreed
financing had to be reduced from $300 to $200 million but Scripps researchers gained the right to
submit research proposals to Novartis, effectively restoring the cut. A comparable agreement,
continued until commercialisation by Novartis, was initiated by Ciba-Geigy with Isis Pharma.
Accordingly, the AIDS-induced retinitis drug, Vitravene was introduced in 1998.
By 1997, Novartis had implemented a new functional genomics strategy. In 2002 a new $250
million genomics research institute in San Diego was announced, named the Genomics Institute of
the Novartis Research Foundation (GNF). The 200 staff complemented in-house research teams at
institutes in Basel and New Jersey (later also Cambridge, Massachusetts for an equivalent
investment16). Several GNF scientists also have faculty appointments at Scripps, and 17% of post-
doctoral researchers work with GNF scientists. GNF also gave rise to the Joint Centre for Structural
Genomics (JCSG) and the Institute for Childhood & Neglected Diseases (ICND) funded as
consortia by the US National Institutes of Health. Scripps and these other institutes are more
entrepreneurial than universities. Intellectual property Novartis is disinterested in can lead to spinout
firms being formed with GNF board members.17 Venture capital comes from the Novartis
BioVenture Fund.18 Established in 2000 with $100 million available, the fund had by 2002 invested
in eleven Californian firms, four of which are in San Diego by which time it had moved its
headquarters from Basel to GNF in La Jolla, San Diego.
Novartis collaborations with DBFs and institutes in San Diego are listed in Table 3. It is worth
noting that many academic as well as DBF partnerships are also made by GNF in San Diego,
including such firms as LifeSpan Biosciences, Molsoft, Syrrxx, Sequenom, Xenogen and Immusol
covering bioinformatics, genetic and proteomic mapping and oncology. In addition GNF partners
the Salk Institute, UC-San Diego and, of course, the Scripps Institute. Hence, it can be seen that the
extended Novartis knowledge chain is deeply embedded in the two
16 This practice was emulated by and from other pharma companies. Currently Aventis is implementing a comparable strategy in Toronto. Meanwhile between 1999 and 2003, Pfizer, Wyeth (acquiring Genetics Institute), Amgen (acquiring Immunex), Aventis (Ariad), Abbott (BASF) and AstraZeneca were all represented in Cambridge, Massachusetts, many through acquisition. However the embedding strategy of Novartis is both distinctive and, in relation to basic research, deeper. 17 In 2000 Syrxx was founded, as were Kalypsys and Phenomix in 2001. 18 Novartis also has a bioincubator at Zug in Switzerland.
20
Year Partner Deal
1989 Cytel Immunosuppression 1990-1995 Isis Pharma Antisense technology
1992 Sibia Amino acids receptors 1992- Scripps Research I. R&D 1995 IDUN Pharma Neurological
1995-1997 Neurocrine Multiple Sclerosis 1997 BioSite Immunosuppression 1998 MolSim Simulation technology 1998 Trega Combinatorial chemistry 1998 CombiChem Combinatorial chemistry
1999 Diversa Seed research 1999 Invitrogen Functional genomics Table 3: Novartis Collaborations with San Diego Biotechnology DBFs & Institutes Source: Zeller, 2004
Californian bioregions but more in the form of a corporate, regional-technological innovation
system in San Diego (and more particularly La Jolla) whereas in San Francisco it is more market
than system-focused. We shall see shortly what the relationships are in Massachusetts, where a new
Novartis Institutes of Biomedical Research opened in 2004. But before that it is worth displaying
equivalent information regarding the other Swiss big pharma representative, Hoffmann-La Roche,
known commercially as Roche (Table 4). The approach taken by Roche involves partnering
agreements with innovative, often relatively immature but
Year Location Partner Deal
1990 San Francisco Genentech 60% stake in firm 1996 San Francisco Gilead Hepatitis C; Influenza
1996-1998 San Francisco PDL Inflammation drug 2000 San Francisco Valeant Anti-viral treatment
2001 San Francisco Telik Proteomics 2001 San Francisco Gryphon Anaemia 2001 San Francisco Tularik Therapeutic antibodies 2002 San Francisco Lipomics Metabolomics 2002 San Francisco Kosan Biosciences Polyketides (organic) 2003 San Francisco Maxygen Interferon; HIV 1998 San Diego Agouron HIV treatment
2000 San Diego Pharmingen Immunology license 2001 San Diego Anadys Anaemia
2002 San Diego Syrrxx Proteomics Table 4: Roche Collaborations with San Francisco & San Diego DBFs Source: Roche and DBF Websites
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specialist DBFs and these located rather more in San Francisco although some are in San Diego.
Many of these agreements are relatively recent, marking a change in Roche strategy from its
acquisition of 60% (nowadays 58.2%) of the highly successful biotechnology pioneer firm
Genentech in 1990 to a more flexible, short-term acquisition of technology and knowledge to fit the
Roche product portfolio. Results for both Californian bioregions are given in Table 4.
Finally, regarding this special in-depth examination of the ‘embedding’ approach of Novartis and, to
a lesser extent Roche as multinational big pharma companies from small country Switzerland,
extending spatial knowledge capabilities by integrating a regional-technological innovation system
within leading global bioregions, what is the evidence from Boston, particularly Cambridge,
Massachusetts, which is arguably the world’s leading genomics research and exploitation
knowledge base? Boston outstrips both San Francisco and San Diego on many but not all
biotechnology benchmarking indicators. In Table 5 the collaborative links of Novartis in the
Cambridge-Boston bioregion are shown. The Roche website revealed none in this
Year Partner Deal 1982-1984 Genetics Institute Immunology; interleukin-2; growth factor 1984-1986 Collaborative Rsch. Cardiac infarction enzyme
1985-1989 Corning Glass Diagnostics 1986 Biogen Vaccine tissue 1989 Repligen Retroviruses 1991 Dana Farber Inst. Oncology & signal transduction R&D agt 1993 Procept Auto-immune substances
1993-2000 BioTransplant Xenotransplantation 1996-1998 Focal Surgery materials
1997 Alexion Viral vectors gene therapy 1997 Avant Immuno Immunotherapeutics transplantation 1999 Cubist Pharma Anti-infection technology
2000 Vertex Pharma Protein kinases research Table 5: Novartis Collaborations with Boston Biotechnology DBFs and Institutes Source: Zeller, 2002 bioregion. The Greater Boston bioregion is well-provided with a diverse set of knowledge
exploration, examination and exploitation institutions and firms (Cooke, 2002). It is clear that
Novartis gains distinctive basic research capabilities in Cambridge-Boston compared to San Diego,
and a further commitment of $4 billion investment beyond that in the Novartis Institutes for
Biomedical Research (NIBR) is testimony to this. NIBR constitutes the primary pharmaceutical-
research arm in the company’s strategy of post-genomic drug discovery, concentrating on the key
therapeutic areas of cardiovascular disease, diabetes, infectious diseases, functional genomics, and
oncology. With the aim to gain a better understanding of the molecular mechanisms of disease the
22
company is integrating previously segregated scientific disciplines, fostering interaction among
scientists from both within and outside of Novartis and developing partnerships with academic
research institutions and DBFs. This was underlined politically by the cities of Boston and Basel
signing a cultural partnership in 2000. Novartis activities in San Diego are more to do with
technologies like databases, combinatorial chemistry, simulation technologies and cloning
technologies and even agricultural research. In San Francisco, the emphasis is more on stem cells
and gene therapy, especially bioinformatics and biochip (GeneChip) technology. This confirms the
inference that Cambridge-Boston is the world-leading post-genomics research bioregion while
California’s bioregions have strength in platform, diagnostic bioinformatics and gene therapy
technologies linked to California’s global excellence in computing and software, and that Novartis
takes advantage from those distinctive knowledge categories in its global drive to redefine the
process of drug discovery.
It is thus evident how Swiss big pharma conducts its research. This can be summarised for Novartis
– one of the leading organisational models for the modern pharmaceuticals industry according to the
following five points.
• Novartis innovation strategy is founded on three supports: internal research; linkage of
internal and external research (e.g. GNF); and collaborations with external partners.
• Collaborations are varied but, first, they support in-house efforts to acquire therapeutic lead
substances, drug targets and disease models, new discovery technologies, and entry into new
fields. Second, partners supply active substances for integration into in-house development
pipeline for clinical trials. A further activity is developing new drug discovery processes, as
in the collaboration with Vertex.
• Collaborations with Scripps Research Institute and Dana Farber Cancer Institute are to get
new hypotheses of diseases and drug targets.
• From such inputs Novartis gets (e.g. with Vertex) exclusive worldwide development,
manufacturing and marketing rights to clinically and commercially relevant drug candidates
it develops with Vertex earning royalties on collaborative products thus marketed.
• Important too, is to organise the optimal R&D mix, concentrating certain research activities
in-house or externally according to corporate competences in the main global locations
of Novartis Centres of Excellence. These are mapped on to globally excellent research
Bioregions.
If we compare that strategy with other big pharma, it is possible to see that Novartis has thought
about and developed the ‘organic’ model of embedding in key bioregions to a fuller extent than any
other big pharma. Most of the others are more market-oriented and opportunistic. For example
23
Glaxo makes partnership arrangements with DBFs but still considers in-house R&D to be a priority
even though its pipeline is drying as in-house R&D fails to deliver significant returns on investment.
Hence, in 2002 seeing biotechnology capabilities being increasingly monopolised by DBFs and
universities, Glaxo restructured its global R&D effort into six main divisions with scientists
liberated from corporate bureaucracy to some extent and incentivised with stock options and
equivalents to emulate DBF research performance. Merck is also of the belief that in-house research
is the preferable form by which corporate R&D should be organised. Alternatively, as we have seen,
Merck engages in short term collaborations and will continue to do so, but meantime intending to
control as much of the R&D chain internally to the corporation. Pfizer has mainly kept its pipeline
from drying by acquisition. Eight of its thirteen new active substances (NAS) derived from its
acquisition of Pharmacia. There is strong evidence that such mega-mergers as the likes of Pfizer and
Glaxo have engaged do not in the long term create greater R&D productivity. Hence Pfizer also has
over 1,000 collaborations with DBFs and research institutes globally to attempt to cover the field for
unexpected new hypotheses or discoveries.
One reason why pharma cannot reduce its collaborations with DBFs and institutes is that not only
does it have declining capability in R&D but also in the kind of competence that it might be thought
economies of scale would actually benefit. However, the following suggests capabilities in
exploiting new technologies, notably high throughput screening (HTS), are no better than research
capabilities. The change from synthetic chemistry to biology as the epistemological basis for
pharmaceuticals companies brought to the fore genetics, database, screening and bioinformatics
technologies allowing pharmaceuticals firms to utilise their natural economies of scale in
experimentation if not basic research. The automated, mass-production analysis of patients and ‘in
silico’ simulations using large databases to mobilise the combinatorial chemistry required to identify
compounds that act as molecular disease-inhibitors gave them an optimistic future. The main reason
concerned time-economies and ‘throughput’ capabilities that only the administrative capabilities of
scale could satisfactorily master19
Intriguing, therefore, to read the following analysis that re-directs our attention from the failings of
‘big pharma’ in basic research, resulting on their heavily increased reliance upon DBF capabilities,
to newly emergent failures in precisely the capabilities identified as those of ‘scale’ that would
triumph in the face of the DBF challenge. Traditionally many pharmaceutical companies had large
industrial-chemical or consumer-products businesses to smooth out the cycles of drug research. The
industry shed those businesses over the years to focus on prescription medicines, which brought
higher stock-market valuations. But the rise of generic copying once patents expired meant
19 This is argued forcefully to be the new core competence of big pharma by Nightingale (2000).
24
companies needing consistently to bring new products to market or lose market-share and profits.
Hence the attraction of ‘combinatorial chemistry’, the new technology of the early to mid-1990s
specifically identified in Nightingale’s (2000) paper. The technology involved selection of chemical
molecules, and their multiple combinations. Machines created thousands of chemicals almost
overnight compared to the weeks humans took to do combinatorial chemistry. Robots connected
elements of each chemical into small vials containing samples of a bodily substance involved in a
disease -- for example, the protein triggering production of cholesterol. If the two reacted in the
desired way, a ‘hit’ was registered, latterly using luminescence technologies in some cases. This
testing process is known as high-throughput screening (HTS). Most large pharmaceutical firms
install the new machines in sites formerly housing their laboratories, and many invested large sums
on contracts with small companies specialising in HTS. For example, GlaxoSmithKline spent more
than $500 million to buy a combinatorial chemistry company.
However the automation processes failed work as anticipated. The head of discovery chemistry at
Bristol-Myers Squibb has referred to the first five or six years of the new technology a ‘nightmare’
observing that many chemists became fixated on creating thousands or millions of chemicals for
testing without thinking about whether any of them could turn into a usable treatment. Test tube
compounds were broken down too easily in the human stomach, issues ‘craft-based’ capabilities
embedded in traditional chemists meant were usually assessed beforehand. Some results meant
scientists were forced to wrestle intellectually with chemicals that were almost impossible to deliver
in humans. The struggle often led to serious delays in development schedules when, for example, a
drug to prevent infection might work in vitro but fail to dissolve in water, the medium used in
intravenous drips.20
We have seen how knowledge networks are the dynamic capabilities that Penrose (1959/1995)
theorised as metamorphosing the global economic order by transforming industry
organisation, and crucially we would argue, heralding a new theory of economic geography.
We call that, tentatively, the Regional Knowledge Capabilities (RKC) theory of economic
geography. It is clear how it operates in regard to Biosciences, possibly also for other S&T
based industries like ICT and new (and old) media – all heavily reliant on networks of project
contracts. Where these are multiple and of relatively short duration they promote clustering
around key knowledge transceiving organisations (Cooke et al., 2004). Where these also
operate in a wider context of organisational and institutional knowledge sharing rather than
knowledge-secreting typical of Industrial Economies as compared to Knowledge Economies
(Cooke, 2002), we may speak of the setting constituting a Regional Innovation System. This
20 This account is given in Landers (2004).
25
is the broader geographical setting where the most important knowledge exploration and
exploitation capabilities concentrate and secondary ones, attracted by increasing returns to
knowledge, including localised knowledge spillovers are found as secondary nodes or even
more diffused networks. There is an established theoretical basis for these processes in the
work of Myrdal (1957) and Hirschman (1958) from which Krugman learned sufficient to
advocate a theory of spatial monopoly based on ‘increasing returns to scale’. However we do
not find the ‘simplistic’ two-location, zero-sum model of spatial monopoly as advocated by
Krugman (1995) convincing.
This is mainly because it is clearly wrong in respect to the evolution of knowledge clusters,
the largest of which may act as megacentres defined by their geographic concentration of the
full knowledge value chain (KVC) of a given industry or sectoral branch. But these exist in
symbiosis with lesser and differentiated nodes and networks. Crucially, unlike the Industrial
Age when these were spatially separated into spatial divisions of labour (Massey, 1984)
knowledge-driven innovation systems concentrate practically everything in a region or regions
with a sectoral knowledge epicentre in an urban or metropolitan R1 (first class research)
university-laboratory complex linked to more and less proximate complementary nodes and
networks.
To round off this account of Basel’s mighty impact from small scale, including utilisation of and
dependence upon small scale DBFs by large pharmaceuticals and agro-food/agro-chemicals
corporations, we may briefly examine the positions of Syngenta and Lonza. Syngenta benefits from
being part of one of the world’s recognisable agro-food ‘clusters’ noted earlier as BioValley (see
Table 6) This is a cross-border network partnership association with Freiburg in Germany and
Strasbourg in France, focused on Life Sciences. The main objective of BioValley is to promote
greater cooperation between companies involved in the biotechnological and biomedical sectors and
the scientific institutions (Basel’s in Table 6) associated with universities in the BioValley area,
most of which have already established close mutual links. This addresses not only pharmaceutical
issues already present in the BioValley area, but also integrates the region's numerous smaller
enterprises and suppliers. It explains the creation of a network focused on knowledge and
technology transfer. This prepares existing companies for global competition, creating employment
in the BioValley region, and stimulating the establishment of new businesses, particularly in
association with universities.
Small in scale, but centrally situated in Europe, BioValley rests on close collaboration between
companies, research institutions, economic development agencies, trade associations and financial
26
service providers. It supports the buoyancy of biotechnology in the cross-border region, helping it to
be competitive with other biotechnology clusters in Europe and further afield. The BioValley
initiative, like the many others around the world specialising mainly in agro-food biotechnology,
sustains systematic collaboration between all those involved in regional innovation.
Countries Bioregion Brand Actors* %Ag-Bio Market Focus Canada Saskatoon (Sk.) ‘Innovation Place’ 115 29 Canola, Flax Guelph (Ont.) ‘Agrifood Quality’ 41 49 Corn USA Connecticut ‘Bioscience Cluster’ 110 1 Corn, fruit Raleigh-Durham ‘Rsch.Triangle Pk.’ 145 3 Corn, soybean St. Louis ‘BioBelt’ 1183 24 Corn, soybean San Diego ‘Biotech Beach’ 700 3 Forestry, fruit, vegetables Europe Scotland ‘Innov. Triangle’ 428 2 Transgenics, potato Sweden ‘Skåne Food Cluster’ 60 25 Functional foods Fr-Ger-Switz. ‘BioValley’ 459 6 Cereals, cotton, livestock Netherlands ‘Food Valley’ 48 60 Food genomics Australia Brisbane (QL.) ‘QBio’ 43 5 Forest, aqua/horticulture Sydney (NSW) ‘BioHub’ 28 18 Livestock, cereal Melbourne (V) ‘Bio21’ 24 4 Plant/animal genomics Adelaide (SA) NA 25 44 Wine, plant/animal gen. Perth (WA) NA 27 20 Wheat, lupins Table 6: Selected Agro-food Bioregions Source: Ryan & Philips (2004); Svensson-Henning (2003); Invest Skane (2004). *NB: Food producers; R&D institutes; raw materials & ingredients suppliers; packaging firms; industry institutes; government agencies; food organisations
Syngenta has seven product lines: crop protection focused on – selective and non-selective
herbicides, fungicides, insecticides and professional products; and seeds – field crops, and
vegetables and flowers. The company was formed by a merger in 2000 when Novartis agribusiness
was spun out and joined Zeneca agrochemicals, similarly spun out from AstraZeneca, as a viable
global business. Syngenta has key research bases in the UK along the M4 Corridor in Berkshire and
in Manchester, at Basel (Stein) and in North Carolina’s Research Triangle Park (RTP) bioregion,21
where most of Syngenta’s biotechnology research is conducted. These laboratories employ 5,000 of
Syngenta’s 20,000 employees. According to the company website22 ‘ …research within Syngenta
complements hundreds of collaborative activities with leading universities, research institutes and
public laboratories…giving Syngenta geographic balance in research and essential pools of
scientific talent.’ Thus, like Novartis and Roche, this global player cannot internally source the
21 In 2001, North Carolina’s Research Triangle Park hosted 910 Life Scientists, with National Institutes of Health (NIH) research funding of $470 million, 2 specialist NIH research institutes, $190 million in alliance financing with ‘big pharma’, and 72 dedicated biotechnology firms (DBFs) with $192 million venture capital funding. It is one of the top seven biotechnology clusters in the US (Cortright & Mayer, 2002). 22 www.syngenta.com/en/about_syngenta/research_tech_where.aspx
27
range of knowledge capabilities it requires, so integrates with DBF clusters23 like RTP and networks
of academic research alliances in public research institutes and university centres.
Lonza is a Life Sciences-driven chemical company headquartered in Basel, with sales of $1.25
billion in 2002 and operating 18 production and R&D facilities in 8 countries. It employs 6 200
people worldwide and is the leading supplier of active chemical ingredients, intermediates and
biotechnology solutions to the pharmaceutical and agrochemical industries. It also offers a broad
range of organic intermediates for numerous applications in pharmaceuticals, agrochemicals,
vitamins, food and feedstuff, dyes and pigments, adhesives and fragrances. Furthermore Lonza
manufactures specialty biocides and oleochemicals and develops and produces specific polymer
intermediates, unsaturated polyester-resins, compounds and composites. Lonza Biologics is the
world’s leading contract manufacturer of therapeutic monoclonal antibodies and recombinant
proteins from mammalian cell culture. Lonza Biotec offers custom microbial fermentation and
biotransformation services to supply intermediates and biologically active products to the life
sciences industry, with applications in pharmaceutical, biotechnological, agrochemical products,
food and feed additives as well as cosmoceutical and nutraceutical products. Hence Lonza occupies
a key manufacturing positioning in the biotechnology value chain.
Conclusions
The empirical section of this paper complements the theoretical and review parts by showing how
microcosms enable macrocosms to function, at least in biotechnology. Thus we examined the Triple
Helix approach to local-regional innovation but found it a too macrosociological, functionalist and
consensus-focused perspective in which the fine texture of specific knowledge capabilities at the
microeconomic level were obscured by the macro-institutional emphasis on large scale institutional
bodies. These seldom, in reality, forge the kinds of links between researchers and business
executives that ultimately create innovation of a systemic kind. We then examined the defensive
‘scale’ perspective against regional science and globalisation’s proposed annihilation of power
relations among networks at the local-regional scale. That was found misguided, unscholarly, linear
and deterministic in its denial of the microprocesses by which research functions on the ground in a
knowledge economy. This perspective favours abstract power structures ‘enveloping’ space over the
23 In 2001, working with Myriad Genetics of Salt Lake City, Utah, Syngenta completed the map of the rice genome, enabling the firm to access the DNA sequence of every rice genotype. Because of its genetic similarity to most other cereals this creates a huge global market for rice and maize breeders, particularly, to improve and accelerate product growth. 80% of the world’s maize goes on feeding livestock. R&D spending was $697 million in 2002. One growth market is seedless melons, being grown in Egypt for the EU market, another is ‘Colossus’ the world’s first hybrid barley, a further innovation is a new phytase enzyme, a substitute for phosphorus in pig and poultry feed. This will be produced through fermentation with Diversa Corporation (San Diego) with whom Syngenta has a research alliance in biotechnology. The enzyme will be grown in corn (maize). Finally a new insect control technology called vegetative insecticidal protein protects cotton and corn crops against insects like root and leaf worms
28
interactive systems explored in the preceding, by means of which global knowledge exploitation is
facilitated.
Taking a Regional Knowledge Capabilities approach proved superior in explaining how research,
innovation and production actually function. That is by regional knowledge capabilities in networks
of the kind Penrose (1959/1995) theorised as firm ‘resources’ of production and administrative
capabilities. From these, a spiral of growth, operating globally is set in motion. What clearly
happens is that capable knowledge actors of various kinds congregate, at least in biotechnology, in a
few particular places we may call clusters or even ‘megacentres’. From these bases knowledge is
transceived locally and globally. This is not the universalist, linear diffusion idealised by the ‘scalar
envelope’ sceptics. Rather network nodes act as key relay points in a global-regional innovation
system. This can easily be shown in pharmaceutical and agro-food biotechnology, by taking the
Regional Knowledge Capabilities theoretical approach. The challenge now is to see whether it
applies equally strongly in other industrial sectors.
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